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<html xmlns="http://www.w3.org/1999/xhtml"><head><link rel="stylesheet" type="text/css" href="insn.css"/><meta name="generator" content="iform.xsl"/><title>BFDOT (indexed)</title></head><body><table style="margin: 0 auto;"><tr><td><div class="topbar"><a href="index.html">Base Instructions</a></div></td><td><div class="topbar"><a href="fpsimdindex.html">SIMD&amp;FP Instructions</a></div></td><td><div class="topbar"><a href="sveindex.html">SVE Instructions</a></div></td><td><div class="topbar"><a href="mortlachindex.html">SME Instructions</a></div></td><td><div class="topbar"><a href="encodingindex.html">Index by Encoding</a></div></td><td><div class="topbar"><a href="shared_pseudocode.html">Shared Pseudocode</a></div></td><td><div class="topbar"><a href="notice.html">Proprietary Notice</a></div></td></tr></table><hr/><h2 class="instruction-section">BFDOT (indexed)</h2><p>BFloat16 floating-point indexed dot product</p>
      <p class="aml">This instruction delimits the source vectors into pairs of BFloat16 elements. The BFloat16 pairs within the second source vector are specified using an immediate index which selects the same BFloat16 pair position within each 128-bit vector segment. The index range is from 0 to 3.</p>
      <p class="aml">If FEAT_EBF16 is not implemented or FPCR.EBF is 0, this instruction:</p>
      <ul>
        <li>
          Performs an unfused sum-of-products of each pair of adjacent BFloat16 elements in the first source vector with the specified pair of elements in the second vector. The intermediate single-precision products are rounded before they are summed, and the intermediate sum is rounded before accumulation into the single-precision destination element that overlaps with the corresponding pair of BFloat16 elements in the first source vector.
        </li>
        <li>
          Uses the non-IEEE 754 Round-to-Odd rounding mode, which forces bit 0 of an inexact result to 1, and rounds an overflow to an appropriately signed Infinity.
        </li>
        <li>
          Flushes denormalized inputs and results to zero, as if FPCR.{FZ, FIZ} is {1, 1}.
        </li>
        <li>
          Disables alternative floating point behaviors, as if FPCR.AH is 0.
        </li>
      </ul>
      <p class="aml">If FEAT_EBF16 is implemented and FPCR.EBF is 1, then this instruction:</p>
      <ul>
        <li>
          Performs a fused sum-of-products of each pair of adjacent BFloat16 elements in the first source vector with the specified pair of elements in the second vector. The intermediate single-precision products are not rounded before they are summed, but the intermediate sum is rounded before accumulation into the single-precision destination element that overlaps with the corresponding pair of BFloat16 elements in the first source vector.
        </li>
        <li>
          Follows all other floating-point behaviors that apply to single-precision arithmetic, as governed by FPCR.RMode, FPCR.FZ, FPCR.AH, and FPCR.FIZ.
        </li>
      </ul>
      <p class="aml">Irrespective of FEAT_EBF16 and FPCR.EBF, this instruction:</p>
      <ul>
        <li>
          Does not modify the cumulative FPSR exception bits (IDC, IXC, UFC, OFC, DZC, and IOC).
        </li>
        <li>
          Disables trapped floating-point exceptions, as if the FPCR trap enable bits (IDE, IXE, UFE, OFE, DZE, and IOE) are all zero.
        </li>
        <li>
          Generates only the default NaN, as if FPCR.DN is 1.
        </li>
      </ul>
      <p class="aml">This instruction is unpredicated.</p>
      <p class="aml">ID_AA64ZFR0_EL1.BF16 indicates whether this instruction is implemented.</p>
    
    <h3 class="classheading"><a id="iclass_sve"/>SVE<span style="font-size:smaller;"><br/>(FEAT_BF16)
          </span></h3><p class="desc"/><div class="regdiagram-32"><table class="regdiagram"><thead><tr><td>31</td><td>30</td><td>29</td><td>28</td><td>27</td><td>26</td><td>25</td><td>24</td><td>23</td><td>22</td><td>21</td><td>20</td><td>19</td><td>18</td><td>17</td><td>16</td><td>15</td><td>14</td><td>13</td><td>12</td><td>11</td><td>10</td><td>9</td><td>8</td><td>7</td><td>6</td><td>5</td><td>4</td><td>3</td><td>2</td><td>1</td><td>0</td></tr></thead><tbody><tr class="firstrow"><td class="l">0</td><td>1</td><td>1</td><td>0</td><td>0</td><td>1</td><td>0</td><td>0</td><td class="r">0</td><td class="lr">1</td><td class="lr">1</td><td colspan="2" class="lr">i2</td><td colspan="3" class="lr">Zm</td><td class="l">0</td><td>1</td><td>0</td><td class="r">0</td><td class="lr">0</td><td class="lr">0</td><td colspan="5" class="lr">Zn</td><td colspan="5" class="lr">Zda</td></tr></tbody></table></div><div class="encoding"><h4 class="encoding"/><a id="bfdot_z_zzzi_"/><p class="asm-code">BFDOT   <a href="#sa_zda" title="Third source and destination scalable vector register (field &quot;Zda&quot;)">&lt;Zda&gt;</a>.S, <a href="#sa_zn" title="First source scalable vector register (field &quot;Zn&quot;)">&lt;Zn&gt;</a>.H, <a href="#sa_zm" title="Second source scalable vector register Z0-Z7 (field &quot;Zm&quot;)">&lt;Zm&gt;</a>.H[<a href="#sa_imm" title="Immediate index of a group of two 16-bit elements within each 128-bit vector segment [0-3] (field &quot;i2&quot;)">&lt;imm&gt;</a>]</p></div><p class="pseudocode">if (!<a href="shared_pseudocode.html#impl-aarch64.HaveSVE.0" title="function: boolean HaveSVE()">HaveSVE</a>() &amp;&amp; !<a href="shared_pseudocode.html#impl-aarch64.HaveSME.0" title="function: boolean HaveSME()">HaveSME</a>()) || !<a href="shared_pseudocode.html#impl-shared.HaveBF16Ext.0" title="function: boolean HaveBF16Ext()">HaveBF16Ext</a>() then UNDEFINED;
integer n = <a href="shared_pseudocode.html#impl-shared.UInt.1" title="function: integer UInt(bits(N) x)">UInt</a>(Zn);
integer m = <a href="shared_pseudocode.html#impl-shared.UInt.1" title="function: integer UInt(bits(N) x)">UInt</a>(Zm);
integer da = <a href="shared_pseudocode.html#impl-shared.UInt.1" title="function: integer UInt(bits(N) x)">UInt</a>(Zda);
integer index = <a href="shared_pseudocode.html#impl-shared.UInt.1" title="function: integer UInt(bits(N) x)">UInt</a>(i2);</p>
  <div class="encoding-notes"/><h3 class="explanations">Assembler Symbols</h3><div class="explanations"><table><col class="asyn-l"/><col class="asyn-r"/><tr><td>&lt;Zda&gt;</td><td><a id="sa_zda"/>
        
          <p class="aml">Is the name of the third source and destination scalable vector register, encoded in the "Zda" field.</p>
        
      </td></tr></table><table><col class="asyn-l"/><col class="asyn-r"/><tr><td>&lt;Zn&gt;</td><td><a id="sa_zn"/>
        
          <p class="aml">Is the name of the first source scalable vector register, encoded in the "Zn" field.</p>
        
      </td></tr></table><table><col class="asyn-l"/><col class="asyn-r"/><tr><td>&lt;Zm&gt;</td><td><a id="sa_zm"/>
        
          <p class="aml">Is the name of the second source scalable vector register Z0-Z7, encoded in the "Zm" field.</p>
        
      </td></tr></table><table><col class="asyn-l"/><col class="asyn-r"/><tr><td>&lt;imm&gt;</td><td><a id="sa_imm"/>
        
          <p class="aml">Is the immediate index of a group of two 16-bit elements within each 128-bit vector segment, in the range 0 to 3, encoded in the "i2" field.</p>
        
      </td></tr></table></div><div class="syntax-notes"/>
    <div class="ps"><a id="execute"/><h3 class="pseudocode">Operation</h3>
      <p class="pseudocode"><a href="shared_pseudocode.html#impl-aarch64.CheckSVEEnabled.0" title="function: CheckSVEEnabled()">CheckSVEEnabled</a>();
constant integer VL = <a href="shared_pseudocode.html#impl-aarch64.CurrentVL.read.none" title="accessor: integer CurrentVL">CurrentVL</a>;
constant integer PL = VL DIV 8;
constant integer elements = VL DIV 32;
constant integer eltspersegment = 128 DIV 32;
bits(VL) operand1 = <a href="shared_pseudocode.html#impl-aarch64.Z.read.2" title="accessor: bits(width) Z[integer n, integer width]">Z</a>[n, VL];
bits(VL) operand2 = <a href="shared_pseudocode.html#impl-aarch64.Z.read.2" title="accessor: bits(width) Z[integer n, integer width]">Z</a>[m, VL];
bits(VL) operand3 = <a href="shared_pseudocode.html#impl-aarch64.Z.read.2" title="accessor: bits(width) Z[integer n, integer width]">Z</a>[da, VL];
bits(VL) result;

for e = 0 to elements-1
    integer segmentbase = e - (e MOD eltspersegment);
    integer s = segmentbase + index;
    bits(16) elt1_a = <a href="shared_pseudocode.html#impl-shared.Elem.read.3" title="accessor: bits(size) Elem[bits(N) vector, integer e, integer size]">Elem</a>[operand1, 2 * e + 0, 16];
    bits(16) elt1_b = <a href="shared_pseudocode.html#impl-shared.Elem.read.3" title="accessor: bits(size) Elem[bits(N) vector, integer e, integer size]">Elem</a>[operand1, 2 * e + 1, 16];
    bits(16) elt2_a = <a href="shared_pseudocode.html#impl-shared.Elem.read.3" title="accessor: bits(size) Elem[bits(N) vector, integer e, integer size]">Elem</a>[operand2, 2 * s + 0, 16];
    bits(16) elt2_b = <a href="shared_pseudocode.html#impl-shared.Elem.read.3" title="accessor: bits(size) Elem[bits(N) vector, integer e, integer size]">Elem</a>[operand2, 2 * s + 1, 16];
    bits(32) sum = <a href="shared_pseudocode.html#impl-shared.Elem.read.3" title="accessor: bits(size) Elem[bits(N) vector, integer e, integer size]">Elem</a>[operand3, e, 32];

    sum = <a href="shared_pseudocode.html#impl-shared.BFDotAdd.6" title="function: bits(N) BFDotAdd(bits(N) addend, bits(N DIV 2) op1_a, bits(N DIV 2) op1_b, bits(N DIV 2) op2_a, bits(N DIV 2) op2_b, FPCRType fpcr_in)">BFDotAdd</a>(sum, elt1_a, elt1_b, elt2_a, elt2_b, FPCR[]);
    <a href="shared_pseudocode.html#impl-shared.Elem.write.3" title="accessor: Elem[bits(N) &amp;vector, integer e, integer size] = bits(size) value">Elem</a>[result, e, 32] = sum;

<a href="shared_pseudocode.html#impl-aarch64.Z.write.2" title="accessor: Z[integer n, integer width] = bits(width) value">Z</a>[da, VL] = result;</p>
    </div>
  <h3>Operational information</h3><p class="aml">
          This instruction might be immediately preceded in program order by a <span class="asm-code">MOVPRFX</span> instruction. The <span class="asm-code">MOVPRFX</span> instruction must conform to all of the following requirements, otherwise the behavior of the <span class="asm-code">MOVPRFX</span> and this instruction is <span class="arm-defined-word">unpredictable</span>:
        </p><ul><li>The <span class="asm-code">MOVPRFX</span> instruction must be unpredicated.</li><li>The <span class="asm-code">MOVPRFX</span> instruction must specify the same destination register as this instruction.</li><li>The destination register must not refer to architectural register state referenced by any other source operand register of this instruction.</li></ul><hr/><table style="margin: 0 auto;"><tr><td><div class="topbar"><a href="index.html">Base Instructions</a></div></td><td><div class="topbar"><a href="fpsimdindex.html">SIMD&amp;FP Instructions</a></div></td><td><div class="topbar"><a href="sveindex.html">SVE Instructions</a></div></td><td><div class="topbar"><a href="mortlachindex.html">SME Instructions</a></div></td><td><div class="topbar"><a href="encodingindex.html">Index by Encoding</a></div></td><td><div class="topbar"><a href="shared_pseudocode.html">Shared Pseudocode</a></div></td><td><div class="topbar"><a href="notice.html">Proprietary Notice</a></div></td></tr></table><p class="versions">
      Internal version only: isa v33.62, AdvSIMD v29.12, pseudocode v2023-03_rel, sve v2023-03_rc3b
      ; Build timestamp: 2023-03-31T11:36
    </p><p class="copyconf">
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